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- Author: Yasuhiro Fujiwara x
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Graduate School of Natural Science and Technology, The Jackson Laboratory, Graduate School of Environmental and Life Science, Okayama University, 1‐1‐1 Tsushima-naka, Kita‐ku, Okayama 700‐8530, Japan
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The ENU-induced repro57 mutation was identified in an unbiased screen for the discovery of novel genes for fertility. Male repro57 homozygous mice are infertile and exhibit significantly reduced testis weight compared with WT mice. Histological examination of mutant testes revealed that spermatocytes degenerated during late prophase, and no mature spermatozoa were found in the seminiferous epithelium, suggesting that infertility is caused by the arrest of spermatogenesis at late meiotic prophase. Consistent with this hypothesis, the number of foci with MLH1, a protein essential for crossing over, is greatly reduced in repro57 mutant spermatocytes, which also lack chiasmata between homologs and exhibit premature dissociation of XY chromosomes. In repro57 mutant mice, we identified a mutation in the Rnf212 gene, encoding Ring finger protein 212. The overall phenotype of repro57 mice is consistent with the recently reported phenotype of the Rnf212 knockout mice; slight differences may be due to genetic background effects. Thus, the repro57 nonsense mutation provides a new allele of the mouse Rnf212 gene.
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Development of the male gonads is a complex process with interaction of various cells in the gonads including germ, Sertoli, Leydig, and myoid cells. TF is a mutant rat strain showing male pseudohermaphroditism, with agenesis of Leydig cells and androgen deficiency controlled by an autosomal single recessive gene (mp). The mp locus was mapped on the distal region of rat chromosome 7 by linkage analysis, but the gene responsible for the mp mutation has not been identified. In this study, we performed fine linkage mapping and sequence analysis to determine the causative gene of the mp mutation, and performed an immunohistochemical study using a Leydig cell-specific marker to investigate detailed phenotypes of the mutant rats during the testicular development. As a result, we found a missense mutation of the gene encoding Desert hedgehog (Dhh) in the mutant rat, which could result in loss of function of the DHH signaling pathway. Histochemical examination revealed remarkably reduced number of fetal Leydig cells and lack of typical spindle-shaped adult Leydig cell in the mp/mp rats. These phenotypes resembled those of the Dhh-null mice. Additionally, testosterone levels were significantly lower in the mp/mp fetus, indicating androgen deficiency during embryonic development. These results indicate that the mutation of the Dhh gene may be responsible for the pseudohermaphrodite phenotypes of the mutant rat, and that the Dhh gene is probably essential for the development of Leydig cells.
The Jackson Laboratory, Bar Harbor, Maine, USA
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Biochemistry and Molecular Pharmacology Department, University of Massachusetts Medical School, Worcester, Massachusetts, USA
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In brief
A new allele of the senataxin gene Setx spcar3 causes meiotic arrest of spermatocytes with aberrant DNA damage and accumulation of R-loops.
Abstract
An unbiased screen for discovering novel mouse genes for fertility identified the spcar3, spermatocyte arrest 3, mutant phenotype. The spcar3 mutation identified a new allele of the Setx gene, encoding senataxin, a DNA/RNA helicase that regulates transcription termination by resolving DNA/RNA hybrid R-loop structures. The Setxspcar3 mutant mice exhibit male infertility and female subfertility. Histology of the Setxspcar3 mutant testes revealed the absence of spermatids and mature spermatozoa in the seminiferous tubules. Cytological analysis of chromosome preparations of the Setxspcar3 mutant spermatocytes revealed normal synapsis, but aberrant DNA damage in the autosomes, defective formation of the sex body, and arrest of meiosis in mid-prophase. Additionally, Setxspcar3 testicular cells exhibit abnormal accumulation of R-loops. Transient expression assays identified regions of the senataxin protein required for sub-nuclear localization. Together, these results not only confirm that senataxin is required for normal meiosis and spermatogenesis but also provide a new resource for the determination of its role in maintaining R-loop formation and genome integrity.
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Assisted Reproductive Technology Center, Okayama University, Tsushimanaka, Kita, Okayama, Japan
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In brief
Repro57 mice, bearing an Rnf212 gene mutation, exhibit infertility in both homozygous mutant males and females, revealing arrested spermatogenesis in males and investigating unclear mechanisms in females. The study highlights aneuploidy and altered kinetochore patterns in repro57 homozygous mutant oocytes, which impact later stages of embryo development.
Abstract
Repro57 mice, induced with N-ethyl-N-nitrosourea and harboring a mutation in the Rnf212 gene, exhibit infertility in both homozygous mutant males and females. Rnf212 plays a crucial role in recombination and crossover designation. In male repro57 homozygous mutants, spermatocytes often degenerate during late prophase, and mature spermatozoa are absent in the seminiferous epithelium, indicating arrested spermatogenesis as the cause of infertility. Despite reports of infertility in Rnf212-knockout female mice, the specific mechanisms underlying infertility in female repro57 homozygous mutants remain elusive. This study investigates the chromosomal and kinetochore patterns of mature oocytes and their developmental potential following in vitro fertilization in female repro57 homozygous mutant mice. While all wild-type oocytes progress to metaphase II and exhibit euploidy, all repro57 homozygous mutant mouse oocytes display aneuploidy. Additionally, kinetochore distances in repro57 homozygous mutant oocytes exceed those observed in wild-type counterparts. Although no significant differences are noted in fertilization and early embryo development rates between wild-type and repro57 homozygous mutant mice, embryos derived from repro57 homozygous mutants exhibit significantly lower morula and blastocyst rates, accompanied by frequent cytokinesis failure and vacuole formation. These findings suggest that the premature segregation of sister chromatids in repro57 homozygous mutant mice adversely impacts the later stages of embryo development.